In 2024, renewable sources accounted for ***** percent of the electricity generated in the United States. The share of renewables in the country's electricity generation has been continually increasing for over a decade. In addition, renewables accounted for over ** percent of the power capacity additions in the U.S. in the same year. Renewable energy sources in the U.S. Wind power was the leading renewable energy source in the country, accounting for over ** percent of the total electricity supply in the U.S., followed by hydropower. Renewable energy generation in the U.S. amounted to *** terawatt-hours in 2023. The growth of renewables in the U.S. According to a recent forecast, the renewable electricity capacity in the U.S. is projected to triple between 2022 and 2040 in a reference scenario, although this figure could be higher in the case of low renewable cost. In 2023, onshore wind and solar photovoltaic energy had some of the lowest levelized cost of electricity in the country.

This table expresses the use of renewable energy as gross final consumption of energy. Figures are presented in an absolute way, as well as related to the total energy use in the Netherlands. The total gross final energy consumption in the Netherlands (the denominator used to calculate the percentage of renewable energy per ‘Energy sources and techniques’) can be found in the table as ‘Total, including non-renewables’ and Energy application ‘Total’. The gross final energy consumption for the energy applications ‘Electricity’ and ‘Heat’ are also available. With these figures the percentages of the different energy sources and applications can be calculated; these values are not available in this table. The gross final energy consumption for ‘Transport’ is not available because of the complexity to calculate this. More information on this can be found in the yearly publication ‘Hernieuwbare energie in Nederland’.

Renewable energy is energy from wind, hydro power, the sun, the earth, heat from outdoor air and biomass. This is energy from natural processes that is replenished constantly.

The figures are broken down into energy source/technique and into energy application (electricity, heat and transport).

This table focuses on the share of renewable energy according to the EU Renewable Energy Directive. Under this directive, countries can apply an administrative transfer by purchasing renewable energy from countries that have consumed more renewable energy than the agreed target. For 2020, the Netherlands has implemented such a transfer by purchasing renewable energy from Denmark. This transfer has been made visible in this table as a separate energy source/technique and two totals are included; a total with statistical transfer and a total without statistical transfer.

Figures for 2020 and before were calculated based on RED I; in accordance with Eurostat these figures will not be modified anymore. Inconsistencies with other tables undergoing updates may occur.

Data available from: 1990

Status of the figures: This table contains definite figures up to and including 2022, figures for 2023 are revised provisional figures and figures for 2024 are provisional.

Changes as of July 2025: Compiling figures on solar electricity took more time than scheduled. Consequently, not all StatLine tables on energy contain the most recent 2024 data on production for solar electricity. This table contains the outdated data from June 2025. The most recent figures are 5 percent higher for 2024 solar electricity production. These figures are in these two tables (in Dutch): - StatLine - Zonnestroom; vermogen en vermogensklasse, bedrijven en woningen, regio - StatLine - Hernieuwbare energie; zonnestroom, windenergie, RES-regio Next update is scheduled in November 2025. From that moment all figures will be fully consistent again. We apologize for the inconvenience.

Changes as of june 2025: Figures for 2024 have been added.

Changes as of January 2025 Renewable cooling has been added as Energy source and technique from 2021 onwards, in accordance with RED II. Figures for 2020 and earlier follow RED I definitions, renewable cooling isn’t a part of these definitions.
The energy application “Heat” has been renamed to “Heating and cooling”, in accordance with RED II definitions. RED II is the current Renewable Energy Directive which entered into force in 2021

Changes as of November 15th 2024 Figures for 2021-2023 have been adjusted. 2022 is now definitive, 2023 stays revised provisional. Because of new insights for windmills regarding own electricity use and capacity, figures on 2021 have been revised.

Changes as of March 2024: Figures of the total energy applications of biogas, co-digestion of manure and other biogas have been restored for 2021 and 2022. The final energy consumption of non-compliant biogas (according to RED II) was wrongly included in the total final consumption of these types of biogas. Figures of total biogas, total biomass and total renewable energy were not influenced by this and therefore not adjusted.

When will new figures be published? Provisional figures on the gross final consumption of renewable energy in broad outlines for the previous year are published each year in June. Revised provisional figures for the previous year appear each year in June.

In November all figures on the consumption of renewable energy in the previous year will be published. These figures remain revised provisional, definite figures appear in November two years after the reporting year. Most important (expected) changes between revised provisional figures in November and definite figures a year later are the figures on solar photovoltaic energy. The figures on the share of total energy consumption in the Netherlands could also still be changed by the availability of adjusted figures on total energy consumption.

Investment into renewable energy technologies has grown significantly in the United States over the last decades. In 2023, investments reached 96.7 billion U.S. dollars, in comparison to 29.1 billion U.S. dollars in 2013. The United States’ renewable market has benefitted from green stimulus programs and uncertainties in renewable tax credits. The United States has also focused heavily on small-scale solar as well as utility-scale renewable technologies. Global renewable investments Investments in clean energy totaled 619 billion U.S. dollars in 2023. China, Europe, and the United States are the largest investors in clean energy worldwide. Solar and wind technologies are the most heavily invested in worldwide. Due to the decrease in the cost of wind and solar technologies, it has been possible to purchase equipment for lower prices.

Large-scale Renewable Projects Reported by NYSERDA Beginning 2004 dataset includes information for projects completed, operational, cancelled, and under development. Projects reported by NYSERDA represent projects which NYSERDA has awarded and approved. For any project awarded in RESRFP24-1 or a subsequent solicitation, this cell will be populated when the project reaches commercial operation and achieves Operational Certification with NYSERDA. This dataset does not represent all renewable projects in New York State. Information pertaining to projects located in Long Island please visit LIPA’s 2024 Report. Projects listed under development are subject to change. For additional information on dataset, please review the data dictionary. Operating Renewable Energy Resources in NYS are reported through the New York Generation Attribute Tracking System and reported annually. Note that all Large Scale Renewable energy projects awarded under solicitations ORECRFP18-1, ORECRFP20-1, ORECRFP22-1,ORECRFP23-1, ORECRFP24-1, RESRFP18-1, RESRFP19-1, RESRFP20-1,RESRFP21-1, RESRFP22-1, RESRFP23-1, RESRFP24-1, BRRFP23-1, T2RFP21-1, and T4RFP21-1 require that all laborers, workpersons, and mechanics, within the meaning of NYS Labor Law Article 8, performing construction activities with respect to the Bid Facility and, if awarded, Energy Storage, must be paid at least the applicable Prevailing Wage applicable in the area where the Bid Facility will be situated, erected and used, as published by the NYS Department of Labor (DOL) or, if located outside of New York State, at least the equivalent Prevailing Wage of the jurisdiction where the Bid Facility is located. For more information on Clean Energy Standard Results, please visit https://www.nyserda.ny.gov/All-Programs/Large-Scale-Renewables/RES-Tier-One-Eligibility/Solicitations-for-Long-term-Contracts For more information on the Offshore Wind Results, please visit https://www.nyserda.ny.gov/All-Programs/Offshore-Wind/Focus-Areas/NY-Offshore-Wind-Projects For more information on the Competitive Tier Two Results, please visit https://www.nyserda.ny.gov/All-Programs/Large-Scale-Renewables/Tier-Two-Competitive-Program For more information on the Tier Four Results, please visit https://www.nyserda.ny.gov/All-Programs/Clean-Energy-Standard/Renewable-Generators-and-Developers/Tier-Four For More Information on Long Island projects, please visit https://www.flipsnack.com/lipower/2024-budget-report/full-view.html For More information on Build-Ready Results, please visit https://www.nyserda.ny.gov/All-Programs/Build-Ready-Program/Build-Ready-Request-for-Proposal The New York State Energy Research and Development Authority (NYSERDA) offers objective information and analysis, innovative programs, technical expertise, and support to help New Yorkers increase energy efficiency, save money, use renewable energy, and reduce reliance on fossil fuels. To learn more about NYSERDA’s programs, visit https://nyserda.ny.gov or follow us on X, Facebook, YouTube, or Instagram.

To reduce Los Angeles' contribution to global warming pollution and to comply with state mandates, DWP is increasing the percentage of its energy that comes from clean renewable power. State mandates require that 33% of power comes from renewables by 2020. For more information, visit www.ladwp.com/ladwp/faces/ladwp/aboutus/a-power/a-p-renewableenergy

In recent years, scrutiny over the environmental impact of more traditional energy sources has translated into a rapid growth of renewables. The share of energy from renewable sources used in electricity generation worldwide has been rising annually, reaching roughly **** percent in 2024. Increasing capacity and production As renewable shares continue to grow, so does the installed capacity. Since 2010 the cumulative renewable energy capacity has risen from *** terawatts to *** terawatts in 2024. Renewable electricity production has also increased significantly, rising to *** petawatt hours in 2022. Despite this impressive and steady growth, the consumption of renewable energy still pales in comparison when compared to fossil fuel energy consumption. Consumption on the rise In the past two decades, global consumption of renewables has risen from just ** exajoules in 2000, to over ** exajoules in 2023. Globally, both China and the United States are the leading consumers of renewable energy, with a combined consumption of ** exajoules.

This API provides international data on renewable electricity capacity and electricity generation. Data organized by country. Users of the EIA API are required to obtain an API Key via this registration form: http://www.eia.gov/beta/api/register.cfm

United States Renewable Energy Market Outlook 2031

The United States renewable energy market size was USD XX Billion in 2022 and is likely to reach USD XX Billion by 2031, expanding at a CAGR of 10.1% during the forecast period, 2023–2031. The growth of the market is attributed to government policies and initiatives to fulfil increased electricity demand using renewable energy sources have been praised.



In 2020, United States electricity generated through renewable energy sources (such as wind, hydropower, solar, biomass, and geothermal energy) a record 834 billion kilowatt-hours (kWh) accounting for around 21% of all electricity generated in the US.

In the United States in 2020, only natural gas (1,617 billion kWh) produced more power than renewables. For the first time in history, renewables outperformed nuclear (790 billion kWh) and coal (774 billion kWh). This result in 2020 was mostly owing to a major reduction in coal use in energy generation in the United States, as well as constantly increasing use of wind and solar.



In 2007, coal-fired electricity output in the United States reached a high of 2,016 billion kWh, although much of that capacity has since been replaced or converted to natural gas-fired power.



Until 2016 coal was the greatest source of electricity in the US, and by 2020 was the first year when renewables and nuclear power provided more electricity than coal (according to our data series that dates back to 1949). Because many nuclear power plants retired and other nuclear facilities suffered slightly more maintenance-related interruptions, nuclear electric generation dropped by Two percent from 2019 to 2020.



With a 42 % rise between 2010 and 2020, renewable energy is the rapidly growing energy source in the United States from 2000 to 2020, it increased by 90%.



In 2020, renewables accounted for about 20% of utility-scale energy generation in the United States, with hydropower <str

This dataset contains GCC Renewable production IRENA for 2008-2019. Data from International Renewable Energy Agency. Export API data for more datasets to advance energy economics research.Data have been obtained from a variety of sources, including: the IRENA questionnaire; official statistics; industryassociation reports; and other reports and news articles. Numbers followed by the letter “o” are figures that havebeen obtained from official sources such as national statistical offices, government departments, regulators andpower companies. The letter “u” follows figures that have been obtained from unofficial sources, such as industryassociations and news articles. The letter “e” follows figures that have been estimated by IRENA from a variety ofdifferent data sources. All figures from the IRENA questionnaire are presented without any indicator.

The global renewable power support policy dataset was compiled by Sarah Hafner (Anglia Ruskin University, United Kingdom) and Johan Lilliestam (Institute for Advanced Sustainability Studies (IASS), Germany) in February-July 2017 and completed during 2017. The work was led by Johan Lilliestam but each author gathered half of the data. The data was formatted and checked for internal consistency by Tim Tröndle, IASS.

All non-commercial users are allowed to use and manipulate our data, but are required to give appropriate attribution. Hence, please cite this data as:

Hafner, S. & Lilliestam, J. (2019): The global renewable power support dataset. Institute for Advanced Sustainability Studies (IASS) & Anglia Ruskin University, Potsdam & Cambridge. Doi: https://doi.org/ 10.5281/zenodo.3371375.

If you are interested in contributing to and further developing the dataset: please contact Johan Lilliestam (IASS Potsdam).

The search was done in publically available sources, including but not limited to the IEA renewables policy database, res-legal.eu, Worldbank data, as well as data from the responsible national ministries.

Our data holds information on 10 specific policy instruments explicitly dedicated to the support for expansion of renewable electricity generation 1990-2016; some instruments, including taxation of non-renewables or emission trading, affect other sectors than renewable power, but are mentioned in their original policy description to also be dedicated to increasing renewable power. Our data concerns national policy measures, but ignores policies enacted on higher (e.g. EU-level in Europe) or lower (e.g. state-level policies in Canada, USA) political levels. For example, the “no support” entry for the United Arab Emirates indicates that there were no national-level policies: all policies were, in this case, emirate-specific.

The data exists in two versions: one version readable for humans (RE_policies_fullglobal.xlsx) and for each instrument type as .csv. The information in the two versions is identical and differs only in the way it is displayed.

Please refer to the metadata file for a detailed description of the dataset and the data categories.

Renewables Management System Market Outlook

The global renewables management system market size was valued at approximately USD 5.3 billion in 2023 and is expected to reach around USD 14.6 billion by 2032, growing at a compound annual growth rate (CAGR) of 12.1% during the forecast period. The growth of this market is primarily driven by the increasing adoption of renewable energy sources, technological advancements, and supportive government policies promoting sustainable energy solutions.

One of the key growth factors in the renewables management system market is the global shift towards sustainable energy solutions. Governments worldwide are implementing stringent regulations and policies to reduce carbon emissions and promote the use of renewable energy sources. This has led to a significant increase in investments in renewable energy projects, thereby driving the demand for efficient management systems to monitor and optimize these resources.

Technological advancements in data analytics, artificial intelligence, and the Internet of Things (IoT) are also playing a crucial role in the market's growth. These technologies enhance the efficiency of renewables management systems by providing real-time data, predictive maintenance, and advanced analytics. As a result, organizations can optimize their renewable energy resources, reduce operational costs, and improve overall efficiency.

Another significant growth factor is the rising awareness among individuals and organizations about the environmental impact of traditional energy sources. There is a growing demand for cleaner and more sustainable energy solutions to combat climate change and reduce greenhouse gas emissions. This trend has led to increased adoption of renewables management systems across various sectors, including utilities, commercial, industrial, and residential.

The concept of Renewable Energy-as-a-Service is gaining traction as businesses and consumers seek flexible and scalable solutions for their energy needs. This model allows users to access renewable energy without the need for significant upfront investments in infrastructure. By subscribing to Renewable Energy-as-a-Service, organizations can benefit from clean energy while focusing on their core operations. This approach not only reduces carbon footprints but also provides predictable energy costs, making it an attractive option for both large enterprises and small businesses. As the demand for sustainable energy solutions continues to rise, the Renewable Energy-as-a-Service model is expected to play a pivotal role in the transition towards a greener future.

From a regional perspective, the Asia Pacific region is expected to witness substantial growth in the renewables management system market. Countries such as China, India, and Japan are investing heavily in renewable energy projects to meet their growing energy demands and reduce their carbon footprint. Additionally, government initiatives and subsidies to promote renewable energy adoption are further fueling the market's growth in this region.

Component Analysis

The renewables management system market is segmented by component into software, hardware, and services. Each of these components plays a critical role in ensuring the efficient management of renewable energy resources. Software solutions in the renewables management system market include tools for monitoring, analytics, and optimization of energy resources. These software solutions utilize advanced algorithms and data analytics to provide real-time insights and predictive maintenance, thereby enhancing the efficiency of renewable energy systems.

Hardware components in the renewables management system market include sensors, meters, and communication devices. These hardware components are essential for capturing real-time data from renewable energy sources, such as solar panels and wind turbines. The data collected by these devices is then transmitted to the software solutions for analysis and optimization. The increasing adoption of IoT and smart grid technologies is driving the demand for advanced hardware components in this market.

Services in the renewables management system market encompass various activities such as installation, maintenance, and consulting. These services are crucial for the successful implementation and ongoing operation of renewables management systems. Companies offering these

List of renewable energy power stations. This Data Package contains a list of renewable energy power plants in lists of renewable energy-based power plants of Germany, Denmark, France and Poland. Germany: More than 1.7 million renewable power plant entries, eligible under the renewable support scheme (EEG). Denmark: Wind and phovoltaic power plants with a high level of detail. France: Aggregated capacity and number of installations per energy source per municipality (Commune). Poland: Summed capacity and number of installations per energy source per municipality (Powiat). Due to different data availability, the power plant lists are of different accurancy and partly provide different power plant parameter. Due to that, the lists are provided as seperate csv-files per country and as separate sheets in the excel file. Suspect data or entries with high probability of duplication are marked in the column 'comment'. Theses validation markers are explained in the file validation_marker.csv. Filtering all entries with comments out results in the recommended data set. Additionally, the Data Package includes a daily time series of cumulated installed capacity per energy source type for Germany. All data processing is conducted in Python and pandas and has been documented in the Jupyter Notebooks linked below.

The UK's energy use from renewable and waste sources, by source (for example, hydroelectric power, wind, wave, solar, and so on) and industry (SIC 2007 section - 21 categories), 1990 to 2023.

Significant electrification of the transportation sector is necessary for the State to achieve several important greenhouse gas (GHG) reduction and renewable energy targets. The State’s electricity generation and transmission capabilities must increase in order to meet the demand generated by increasing levels of fleet electrification. The increased demand, combined with the Renewables Portfolio Standard (RPS) targets will require significantly increased energy storage capabilities that can accommodate demand while integrating renewable power sources into the grid. This project evaluated the mid to long-term energy storage needs of the electric grid for select fleet electrification scenarios. The analysis was conducted using Resolve, a power systems planning model, for RPS targets of 60% and 80% by 2030 and 2042 respectively. The results show that Electrical Energy Storage (EES) capacity requirements depend on a number of parameters, including Demand Response (DR), Electric Vehicle (EV) charging flexibility, and total EV population. The EES requirements for the 60% RPS scenarios range from 3.9 to 4.3 GW while for the 80% RPS scenarios, the range is from 18.5 to 20.4 GW.

Renewables Alerts

## Overview

Renewables Alerts is a dataset for object detection tasks - it contains Energy annotations for 1,988 images.

## Getting Started

You can download this dataset for use within your own projects, or fork it into a workspace on Roboflow to create your own model.

  ## License

  This dataset is available under the [CC BY 4.0 license](https://creativecommons.org/licenses/CC BY 4.0).

Renewable Energy Market Outlook

According to our latest research, the global renewable energy market size reached USD 1.35 trillion in 2024, reflecting a robust expansion driven by global sustainability initiatives and technological advancements. The market is projected to grow at a CAGR of 9.8% from 2025 to 2033, reaching a forecasted value of USD 3.17 trillion by 2033. This exceptional growth is primarily attributed to the increasing adoption of clean energy technologies, government incentives, and the urgent need to mitigate climate change impacts. The renewable energy market is experiencing a paradigm shift as nations and industries prioritize decarbonization and energy security, making it a cornerstone of the global energy transition.

One of the most significant growth factors for the renewable energy market is the escalating global demand for clean and sustainable energy sources. Governments worldwide are implementing stringent policies and offering attractive subsidies to accelerate the transition from fossil fuels to renewable alternatives. The Paris Agreement and other international climate accords have set ambitious targets for reducing greenhouse gas emissions, compelling countries to invest heavily in renewable infrastructure. This policy-driven momentum is further supported by rising public awareness about environmental issues and the long-term economic benefits of renewable energy, creating a fertile landscape for market expansion.

Technological innovation is another key driver propelling the renewable energy market forward. Advances in photovoltaic cells, wind turbine efficiency, and energy storage solutions have significantly reduced the cost of renewable power generation, making it increasingly competitive with traditional energy sources. The integration of digital technologies such as artificial intelligence, IoT, and blockchain is optimizing energy management, grid integration, and predictive maintenance, further enhancing the reliability and scalability of renewable energy systems. As technology continues to evolve, the barriers to entry are diminishing, enabling broader adoption across diverse sectors and geographies.

Another critical growth factor is the increasing participation of the private sector and financial institutions in renewable energy projects. Investments from venture capital, private equity, and green bonds are fueling the development of large-scale solar farms, wind parks, and bioenergy facilities. Corporate power purchase agreements (PPAs) are also gaining traction, with multinational companies committing to sourcing 100% of their energy from renewables. This influx of capital and corporate commitment is accelerating the commercialization of emerging technologies and fostering innovation across the renewable energy value chain, driving sustained market growth.

From a regional perspective, Asia Pacific stands out as the fastest-growing market for renewable energy, led by China, India, and Japan. The region’s rapid industrialization, population growth, and urbanization are creating substantial energy demand, which is increasingly being met through renewable sources. Europe remains a leader in policy innovation and market integration, while North America is witnessing a surge in corporate renewable procurement and decentralized energy systems. Latin America and the Middle East & Africa are also emerging as key players, leveraging abundant natural resources and international financing to expand their renewable energy portfolios.

Type Analysis

The renewable energy market is segmented by type into solar energy, wind energy, hydropower, bioenergy, geothermal energy, and others. Among these, solar energy has emerged as the dominant segment, accounting for the largest share of new capacity additions in recent years. The widespread adoption of photovoltaic (PV) technology, coupled with declining module prices and supportive policy frameworks, has made solar energy accessible to residential, commercial, and utility-scale consumers. Sola

Monthly and annual data on renewable energy, i.e., biomass, geothermal, hydropower, solar, and wind. Also data on alternative transportation fuels, i.e., hydrogen, natural gas, propane, ethanol, and electricity. Data on renewable energy production, consumption, electricity generation, and consumption by end-use sector.

This file ‘all_areas_dataframe_renewables_and_non_renewables.xlsx’ is the result of the notebook https://www.kaggle.com/code/fords001/renewable-and-non-renewable-electricity-resources . It contains information from the years 2000 to 2023 and includes 18 sheets: for the percentage of electricity generation and for electricity generation in terawatt-hours (TWh) for each of the following world regions: Africa, Europe, Asia, North America, Latin America and the Caribbean, Oceania, as well as for the entire world. Each region has 11 columns representing different sources of electricity generation: Non-Renewables: Coal, Gas, Nuclear, Other Fossil (4 columns), Renewables: Bioenergy, Hydro, Solar, Wind, Other Renewables (5 columns). For each world region, we have two additional columns: Total Non-Renewables (1 column) and Total Renewables (1 column), which will be the sum of the related electricity generation columns .

List of dataframes : 'All_Areas_Common_Percent ' - Percentage dataframe for all areas 'All_Areas_Common_TWh' - Terawatt-hours dataframe for all areas 'All_Areas_Percent_Ren_Non_R' - Percentage df for all areas for 2 columns(Non-Renewables , Renewable) 'All_Areas_TWh_Ren_and_Non_R' - TWh df for all areas for 2 columns(Non-Renewables , Renewable) 'World_DF_Percent' - World dataframe Percentage 'World_DF_TWh' - World dataframe Terawatt-hours 'Africa_DF_Percent' - Africa dataframe Percentage 'Africa_DF_TWh' - Africa dataframe Terawatt-hours 'Europe_DF_Percent' - Europe dataframe Percentage 'Europe_DF_TWh' - Europe dataframe Terawatt-hours 'Asia_DF_Percent' - Asia dataframe Percentage 'Asia_DF_TWh' - Asia dataframe Terawatt-hours 'North_America_DF_Percent' - North America dataframe Percentage 'North_America_DF_TWh' - North America dataframe Terawatt-hours 'Latin_America_and_C_DF_Percent' - World dataframe Percentage 'Latin_America_and_C_DF_Twh' - World dataframe Terawatt-hours 'Oceania_DF_Percent' - Oceania dataframe Percentage 'Oceania_DF_TWh' - Oceania dataframe Terawatt-hours

In this data analysis I used the dataset ‘yearly_full_release_long_format.csv’, from https://ember-energy.org/data/yearly-electricity-data/ .It has a license (Creative Commons Attribution Licence (CC-BY-4.0). This license means. Share — copy and redistribute the material in any medium or format for any purpose, even commercially. Adapt — remix, transform, and build upon the material for any purpose, even commercially. The licensor cannot revoke these freedoms as long as you follow the license terms. These are the links to the license description . https://ember-energy.org/creative-commons/ and https://creativecommons.org/licenses/by/4.0/